Physical states of a pharmaceutical drug substance

ABSTRACT

An amorphous form of imipramine pamoate, morphologically pure forms, and mixtures of amorphous and morphologically pure imipramine pamoate characterized by differential scanning calorimetry, fourier transform infrared, and powder x-ray diffraction, and pharmaceutical compositions formed therefrom.

BACKGROUND

Practically, pamoic acid salts of active pharmaceutical ingredients(APIs) have received very little attention either by pharmaceuticalscientists or synthetic organic chemists. Two simplistic observationsare recurring themes in the folklore (i.e. industry practice or belief)surrounding pamoic acid derivatives. In general, the preparation of apamoate salt converts a liquid material to a solid and an improvedorganoleptic property has been ascribed to such salts. Organolepticproperties, for example, are smell and taste, and pamoate salts of drugsubstances have been suggested as eliminating the bitter taste comparedwith other salts (or the free base) of the drug substance. Rationallyand chemically, these attributes can be assigned to pamoate salts.

It is of some historical interest that the pamoate salts of a variety ofactive pharmaceutical ingredients have received attention, noting thatan embonate salt is identical to a pamoate salt. In the following citedliterature, the pamoate was apparently chosen a) for converting a liquidactive pharmaceutical ingredient into a solid, b) for eliminating thebitter taste associated with many active pharmaceutical ingredients, orc) as a process for isolating and then chemically characterizingotherwise difficult to delineate alkaloids or active pharmaceuticalingredients. For instance, U.S. Pat. No. 5,232,919 [Scheffler, et al.],the disclosure of which is totally incorporated herein by reference,discloses azelastine embonate and pharmaceuticalformulations/compositions which contain it; said embonate salt toeliminate the bitter taste of azelastine alone.

Further, the French Patent 1,461,407 [Saias, et al.], the disclosure ofwhich is totally incorporated herein by reference, discloses a processfor the preparation of amine pamoates where the amine component includespiperazine, promethazine, papaverine, pholocodine, codeine, narcotineand chlorpheniramine.

The United Kingdom Patent Specification 295,656, [Carpmaels & Ransford,agents for applicants] the disclosure of which is totally incorporatedherein by reference, discloses a process for the manufacture of poorlysoluble salts of organic bases and alkaloids. The disclosure furtherindicates the process for manufacture provides sparingly soluble andtasteless salts of organic nitrogenous basic compounds includingalkaloids.

U.S. Pat. No. 3,502,661 [Kasubick, et al.], the disclosure of which istotally incorporated herein by reference, discloses a process for thepreparation of variously substituted pyridinium and imidazolines alongwith their acid addition salts. Some examples indicate pamoate saltsprepared for select organic bases.

U.S. Pat. No. 2,925,417 [Elslager, et al.], the disclosure of which istotally incorporated herein by reference, discloses quinolinium salts ofpamoic acid and a process for their manufacture.

Further, the following cited references indicate the incorporation ofpamoate salts in pharmaceutical formulations for providing thecontrolled release of water insoluble polypeptides or the oil solubleazelastine. Hence, U.S. Pat. No. 5,776,885 [Orsolini, et al.], thedisclosure of which is totally incorporated herein by reference,discloses a pharmaceutical composition for the sustained and controlledrelease of water insoluble polypeptides whereby the therapeuticallyactive peptide is in the form of its pamoate, tannate or stearate salt.

U.S. Pat. No. 5,445,832 [Orsolini, et al.], the disclosure of which istotally incorporated herein by reference, discloses a process for thepreparation of microspheres made of a biodegradable polymeric materialwhereby a water soluble peptide or peptide salt is converted into acorresponding water-insoluble peptide salt selected from pamoates,stearates or palmitates of the peptide.

U.S. Pat. No. 5,439,688 [Orsolini, et al.], the disclosure of which istotally incorporated herein by reference, discloses a process forpreparing a pharmaceutical composition in the form of microparticlesdesigned for the controlled release of a drug that includes abiodegradable polymer and where the active ingredient can be selectedfrom a group of possible salts, one being a pamoate.

U.S. Pat. No. 5,271,946 [Hettche] the disclosure of which is totallyincorporated herein by reference, discloses a controlled releaseazelastine containing pharmaceutical composition whereby azelastine isincorporated into the formulation as its pamoate or otherpharmaceutically active salt.

U.S. Pat. No. 5,225,205 [Orsolini, et al.], the disclosure of which istotally incorporated herein by reference, discloses a pharmaceuticalcomposition in the form of microparticles; the formulation consisting ofa peptide as its pamoate, tannate, stearate or palmitate salt; theformulation to provide a controlled release, pharmaceutical compositionfor the prolonged release of a medicamentous substance.

While the patent literature describes a number of known activepharmaceutical ingredients as their pamoate salts, surprisingly the Foodand Drug Administration (FDA) has only three commercial productscurrently approved containing the pamoate moiety. These products arehydroxyzine pamoate, imipramine pamoate and triptorelin pamoate.Clearly, the pamoate moiety is an under-represented class ofpharmaceutical salts and there remains a need to further explore thebenefits available from producing pamoate salts of APIs.

In their Guidance for Industry, ANDAs: Pharmaceutical SolidPolymorphism, the United States Food and Drug Administration (FDA) hasfocused attention on the importance of characterizing the polymorphicbehavior of an Active Pharmaceutical Ingredient (API) and the impactthat behavior has on the commercial presentation of a formulated drugproduct. Indeed, the physical and chemical properties of an API'sdifferent polymorphs often display different behavior in their intendedapplication and are known to influence and/or impact propertiesimportant to pharmaceutical compositions. These properties include theAPI's bioavailability, solubility, dissolution behavior, stabilityprofile, permeability and manufacturing handling robustness includingbut not limited to uniformity of mixing, compaction in compression stepsfor tablet making, and the flow characteristics of the bulk blend.

The pharmaceutical industry has responded to the cited FDA Guidance anda number of patents have been allowed that provide solutions to a hostof problems arising from polymorphic issues. In some cases, a givenissue or problem was resolved by formulating a drug product with aspecific API polymorph. In other cases, a new API polymorph was isolatedand characterized to overcome prior art and/or to solve a technicalissue. A few examples are representative of the substantive activity inpolymorph research and development for pharmaceutical compositions.

A method for obtaining the most thermodynamically stable polymorph offormoterol tartrate and its subsequent purification by recrystallizationis described in U.S. Pat. No. 6,472,563 (Tanoury, et al.), incorporatedherein by reference. Tanoury et al. in U.S. Pat. No. 6,720,453, thedisclosure of which is totally incorporated herein by reference, also inrelation to formeterol tartrate polymorphs, describe a process forobtaining a highly pure salt of a single enantiomer of the API.

An instructive series of patents include U.S. Pat. No. 5,736,541[Bunnell et al.], U.S. Pat. No. 6,251,895 B1 [Larsen et al.] and U.S.Pat. No. 7,022,698 B2 [Hamied et al.], the disclosure of each is totallyincorporated herein by reference, and relate to the polymorphic forms ofolanzapine and its use in pharmaceutical compositions. The API,olanzapine, has been isolated and characterized in several differentfree-base, polymorphic forms with each polymorph demonstrating adifferent stability profile and each subject to formulation changessuitable for use as a final dose product.

U.S. Pat. No. 5,120,850 [Bod et al.] and U.S. Pat. No. 5,128,477 [Bod etal.], the disclosure of each being totally incorporated herein byreference, relates to the selective crystallization or precipitation oftwo morphologically homogeneous forms of famotidine, a thiazolederivative. In U.S. Pat. No. 4,283,408 [Hirata et al.], the disclosureof which is totally incorporated herein by reference, famotidine and itspharmaceutically acceptable salts were formulated into gastric acidsecretion inhibitors.

Recently, U.S. Pat. No. 6,987,111 B2 [Greco et al], the disclosure ofwhich is totally incorporated herein by reference, disclosespharmaceutical compositions possessing long acting and/or extendedrelease profiles incorporating the pamoate salts of aripiprazole,olanzapine and haloperidol. The inventors' observations contained intheir claims purports to the physical appearance of the salt as aneedle, or as crystalline, however no polymorphic examination,dissolution profile, bioavailability or pharmacokinetics was reported.

An important issue surrounding the current unprecedented activity ingeneric drug development is the evaluation of existing pharmaceuticalproducts to identify their polymorphic behavior and to incorporate thecorrect polymorph into a generic commercial offering. Simultaneously,the generic product must exhibit a favorable impurity profile comparedto the original, innovator product. Frequently for older drug products,the degree to which the active ingredient may be present in one or morepolymorphic forms has not been explored or well characterized (if atall). Different polymorphic forms can radically influence a drug'ssolubility and result in a dramatically altered pharmacokinetic behaviorfor the patient.

To demonstrate the preceding assertion, U.S. Pat. No. 3,326,896[Holstius] is illustrative, and the disclosure of which is totallyincorporated herein by reference. The author discloses three embonic(pamoic acid) addition salts free from unpleasant taste and localanesthetic properties, and useful for the treatment of depression. Theaddition salt of5-(3-dimethylaminopropyl)dihydro-5H-dibenz-[b,f]-azepine, (imipramine),was absorbed more slowly than the corresponding hydrochloride salt.Processes for making the embonic acid addition salts in aqueous andorganic media were also disclosed. A review of the reported laboratorywork reveals an anomalous observation in that the same “melting point”was reported for the pamoate salt of5-(3-dimethylaminopropyl)-10,11-dihydro-5H-dibenz[b,f]azepine as for5-(3-methylaminopropyl)-10,11-dihydro-5H-dibenz[b,f]azepine derivative.Both “melting points” were reported as 125-150° C. even though they aredifferent compounds prepared under the same aqueous conditions. Meltingranges of this magnitude are generally associated with the presence ofimpurities and/or the presence of solvates/hydrates. In connection withthe material the authors isolated, no crystalline forms were observed orclaimed, and indeed, no attempt was made to characterize crystallineforms through techniques such as microscopy or X-ray powder diffractionpatterns. Further, no calorimetry was performed thus clues gleaned fromheats of fusion or heats of hydration were not provided. Interestingly,the author claims the embonic acid addition salt of5-(3-dimethylaminopropyl)-10,11-dihydro-5H-dibenz[b,f]azepine, howeverthe salt is not characterized as the 1:1 salt or as the 2:1 salt or somemixture thereof. Perhaps the broad melting point reported in thespecification suggests the presence of impurities and/or the presence ofunidentified solvates or hydrates.

With the existing commercial need and societal demand for generic drugproducts, the current invention is directed toward novel polymorphicforms of imipramine pamoate and their subsequent purification.

SUMMARY

It is an object of the invention to provide improved forms of imipraminepamoate and improved control over the morphology generated during theformation thereof.

A particular feature of the present invention is the ability tocharacterize imipramine pamoate morphologies and to control the ratio ofdefined morphologies for imipramine pamoate.

These and other advantages, as will be realized, are provided in anamorphous form of imipramine pamoate characterized by a differentialscanning calorimetry (DSC) thermogram exhibiting a phase transition ofabout 105-113° C. and a heat of fusion of at least 0.5 joules per gram.

Yet another advantage is provided in an amorphous form of imipraminepamoate characterized by an infrared (IR) absorbance spectrum as of FIG.6.

Yet another advantage is provided in an amorphous form of imipraminepamoate characterized by a powder X-ray diffraction (PXRD) diffractionpattern as of FIG. 1.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a differential scanning calorimetry (DSC)thermogram exhibiting phase transitions at about 108-115° C. and atabout 137-151° C. and having associated heats of fusion of at least 0.5Joules per gram and 8 Joules per gram respectively.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by an infrared (IR) absorbance spectrum as of FIG.7.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a powder X-ray diffraction (PXRD) pattern as ofFIG. 2.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a differential scanning calorimetry (DSC)thermogram exhibiting a phase transition of about 160-171° C. and a heatof fusion of at least 2 Joules per gram.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by an infrared (IR) absorbance spectrum as of FIG.3.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a powder X-ray diffraction (PXRD) pattern as ofFIG. 3.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a differential scanning calorimetry (DSC)thermogram exhibiting a phase transition at about 140-160° C. heat offusion of at least 18 Joules per gram.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by an infrared (IR) absorbance spectrum as of FIG.9.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a powder X-ray diffraction (PXRD) pattern as ofFIG. 4.

Yet another advantage is provided in a polymorphic blend of imipraminepamoate Form I and imipramine pamoate Form III characterized by adifferential scanning calorimetry (DSC) thermogram exhibiting phasetransitions of about 60-110° C. and at about 150-170° C. and eachpossessing a heat of fusion is at least 10 Joules per gram.

Yet another advantage is provided in a polymorphic blend of imipraminepamoate Form I and imipramine pamoate Form III characterized by aninfrared (IR) absorbance spectrum as of FIG. 10.

Yet another advantage is provided in a polymorphic blend of imipraminepamoate Form I and imipramine pamoate Form III characterized by a powderX-ray diffraction (PXRD) pattern as of FIG. 5.

Yet another advantage is provided in a process for preparing purifiedforms of imipramine pamoate comprising the steps:

a) combining the pH adjusted solutions of imipramine hydrochloride anddisodium pamoate at a metered or unmetered rate of combination,

b) adding an organic solvent to the reaction mixture during the reagentcombining step or afterward,

c) warming the reaction solution to a temperature less than or equal tothe added solvent's azeotropic boiling point,

d) cooling and precipitating solids from the reaction mixture

e) collecting the precipitated solids by filtration or centrifugation,

f) optionally washing the collected solids with water, solvent or amixture thereof,

g) drying the solids, optionally under vacuum at temperatures sufficientto remove the water and solvent, and

h) assessing the quality of the dried solid by chromatographic methods.

Yet another advantage is provided in a blend of at least one imipraminepamoate polymorphic form with another form.

Yet another advantage is provided in a process for preparing a mixtureof polymorphic forms of imipramine pamoate comprising the steps of

a) a process temperature change during the reaction between imipramineas its mineral acid salt with a solution of pamoic acid or its salt suchthat the temperature of reaction providing a lower melting point form isincreased to the temperature range which provide at least one second,higher melting polymorph, andb) the addition of a secondary solvent capable of allowing the reactiontemperature to increase to that temperature where at least oneadditional polymorph is formed, andc) a process temperature change during drying of the isolated solids forthe reaction mixture such that the temperature is increased for a timeperiod required to produce at least one additional polymorph,

Yet another advantage is provided in a process for preparing a mixtureof polymorphic forms of imipramine pamoate comprising the steps of:

a) preparing the individual forms to be blended selected from the groupdefined as Form I, Form II, Form III, Form IV, Form V and Form VI.

b) combining the desired forms of imipramine pamoate in a pre-determinedweight ratio of each component in a common vessel,

c) mixing, blending, tumbling, rotating, or by other mechanical actionto insure and assure homogenous intermixing of the two forms, and

d) assessing the quality of the polymorphic blend by analyticalmethodology selected from differential scanning calorimetry (DSC),Infrared absorption (IR), powder x-ray diffraction (PXRD) andchromatographic methodology.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a differential scanning calorimetry (DSC)thermogram exhibiting phase transitions at about 98-118° C. and at about128-145° C. and having associated heats of fusion of at least 50 and 8Joules per gram, respectively,

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by an infrared (IR) absorbance spectrum consistentwith and generally comparable to that represented by FIG. 19.

Yet another advantage is provided in a polymorphic form of imipraminepamoate characterized by a powder X-ray diffraction (PXRD) patternconsistent with and generally comparable to that represented in FIG. 18.

Yet another advantage is provided in a synthetic process capable ofproducing multiple polymorphic forms of imipramine pamoate comprising atleast one step selected from isolating amorphous imipramine pamoate fromthe reaction vessel; isolating amorphous imipramine pamoate incombination with a selected polymorphic form of imipramine pamoate;isolating a single polymorphic form of imipramine pamoate and isolatinga mixture of polymorphic forms of imipramine pamoate.

Yet another advantage is provided in a synthetic process capable ofinter-converting physical forms of imipramine pamoate comprising atleast one step selected from subjecting amorphous imipramine pamoate tosolvent and temperature conditions sufficient for generating an amountof polymorphic imipramine pamoate from 1-100% of the single polymorph;subjecting an imipramine pamoate polymorph exhibiting a lower phasetransition temperature to solvent and temperature conditions sufficientfor generating an amount of a second polymorphic form of imipraminepamoate from 1-100% and said second polymorphic form having a higherphase transition temperature and subjecting a mixture of amorphousimipramine pamoate and an imipramine pamoate polymorph exhibiting alower phase transition temperature to solvent and temperature conditionssufficient for generating an amount of a second polymorphic imipraminepamoate from 1-100%, and said second polymorphic form having a higherphase transition temperature.

Yet another advantage is provided in a pharmaceutical composition of atleast one polymorphic form of imipramine pamoate suitable for use intreating depression, fibromyalgia, childhood nocturnal enuresis andadult urinary incontinence, trichotillomania, post-traumatic stressdisorder, panic disorder and to provide analgesic-like relief forneuropathic pain.

Yet another advantage is provided in a pharmaceutical compositioncomprising a polymorphic form of imipramine pamoate comprising at leastone material selected from the group consisting of imipramine pamoateForm I, imipramine pamoate Form II, imipramine pamoate Form III,imipramine pamoate Form IV, imipramine pamoate Form V and imipraminepamoate Form VI adapted for use in treating depression, fibromyalgia,childhood nocturnal enuresis and adult urinary incontinence,trichotillomania, post-traumatic stress disorder, panic disorder and toprovide analgesic-like relief for neuropathic pain.

Yet another advantage is provided in a pharmaceutical compositioncomprising 1 to 95% amorphous imipramine pamoate and 5-99 wt % of atleast one material selected from imipramine pamoate Form II, imipraminepamoate Form III, imipramine pamoate Form IV, imipramine pamoate Form Vand imipramine pamoate Form VI.

Yet another advantage is provided in a process capable ofinter-converting physical forms of imipramine pamoate at least one stepselected from optionally subjecting amorphous imipramine pamoate tosolvent and temperature conditions sufficient for generating an amountof polymorphic imipramine pamoate from 1-100% of the single polymorph;optionally subjecting an imipramine pamoate polymorph exhibiting a lowerphase transition temperature to temperature conditions sufficient forgenerating an amount of a second polymorphic form of imipramine pamoatefrom 1-100% and said second polymorphic form having a higher phasetransition temperature; optionally subjecting a mixture of amorphousimipramine pamoate and an imipramine pamoate polymorph exhibiting alower phase transition temperature to temperature conditions sufficientfor generating an amount of a second polymorphic imipramine pamoate from1-100%, and said second polymorphic form having a higher phasetransition temperature and optionally subjecting a mixture of amorphousimipramine pamoate and an imipramine pamoate polymorph to temperaturecondition sufficient for substantially converting the amorphousimipramine pamoate to the said imipramine pamoate polymorph.

Yet another advantage is provided in a pharmaceutical compositioncomprising:

0-100 wt % of imipramine pamoate with a phase transition of 105-133° C.and a heat of fusion of at least 0.5 joules per gram;

0-100 wt % of imipramine pamoate with a phase transition of 108-115° C.with a heat of fusion of at least 0.5 joules per gram and a phasetransition of 137-151° C. with a heat of fusion of at least 8 joules pergram;

0-100 wt % of imipramine pamoate with a phase transition of 160-171° C.and a heat of fusion of at least 2 joules per gram;

0-100 wt % of imipramine pamoate with a phase transition of 140-160° C.and a heat of fusion of at least 18 joules per gram;

0-100 wt % of imipramine pamoate with a phase transition of about60-110° C. with a heat of fusion of at least 15 joules per gram and aphase transition of about 150-170° C. with a heat of fusion of at least15 joules per gram; and

0-100 wt % of imipramine pamoate with a phase transition of about98-118° C. with a heat of fusion of at least 30 joules per gram and aphase transition of about 128-145° C. with a heat of fusion of at least5 joules per gram.

BRIEF DESCRIPTION OF FIGURES

FIG. 1 is an x-ray diffraction pattern of imipramine pamoate Form I.

FIG. 2 is an x-ray diffraction pattern of imipramine pamoate Form II.

FIG. 3 is an x-ray diffraction pattern of imipramine pamoate Form III.

FIG. 4 is an x-ray diffraction pattern of imipramine pamoate Form IV.

FIG. 5 is an x-ray diffraction pattern of imipramine pamoate Form V.

FIG. 6 is a Fourier Transform Infrared spectrum of imipramine pamoateForm I.

FIG. 7 is a Fourier Transform Infrared spectrum of imipramine pamoateForm II.

FIG. 8 is a Fourier Transform Infrared spectrum of imipramine pamoateForm III.

FIG. 9 is a Fourier Transform Infrared spectrum of imipramine pamoateForm IV.

FIG. 10 is a Fourier Transform Infrared spectrum of imipramine pamoateForm V.

FIG. 11 is a differential scanning calorimetry thermogram of anembodiment of imipramine pamoate Form I.

FIG. 12 is a differential scanning calorimetry thermogram of anotherembodiment of imipramine pamoate Form II.

FIG. 13 is a differential scanning calorimetry thermogram of imipraminepamoate Form III.

FIG. 14 is a differential scanning calorimetry thermogram of imipraminepamoate Form IV.

FIG. 15 is a differential scanning calorimetry thermogram of imipraminepamoate Form V.

FIG. 16 is a high performance liquid chromatography chromatograph of anembodiment of the present invention.

FIG. 17 is a high performance liquid chromatography chromatograph ofanother embodiment of the present invention.

FIG. 18 is an x-ray diffraction pattern of another embodiment of amixture of imipramine pamoate Form I and of imipramine pamoate Form VI.

FIG. 19 is a Fourier Transform Infrared spectrum of a mixture ofimipramine pamoate Form I and of imipramine pamoate Form VI.

FIG. 20 is a differential scanning calorimetry thermogram of a mixtureof imipramine pamoate Form I and of imipramine pamoate Form VI.

FIG. 21 is a differential scanning calorimetry thermogram of imipraminepamoate Form II after annealing.

DETAILED DESCRIPTION

The invention described herein and supported by the accompanyingEXAMPLES and FIGURES discloses novel, polymorphic forms (includingamorphous and blended forms) of imipramine pamoate and their utility inpharmaceutical compositions. The invention also describes a means toprovide highly purified forms of these polymorphs and stable mixtureshaving at least one polymorph in combination with amorphous material.

FIGS. 1 through 5, and FIG. 18 are the diffractograms obtained frompowder X-ray diffraction (PXRD) analysis of polymorphic forms, (orblends) described as Form I, Form II (a mixture containing amorphousmaterial), Form III, Form IV, Form V (a physical mixture containing atleast two forms), and Form VI (a process mixture containing at least twoforms), respectively. An analytical difference characterizes eachdiffractogram and allows for the identification of each polymorph. Inthe diffractograms minor impurities of sodium chloride are indicated bypeaks at about 32, 45, 57 and 66 degrees 2-theta. These are consideredto be non-consequential impurities and of no significance in thematerial. The presence, or absence, of these peaks does not alter theinterpretation or comparison of the underlying diffractogram which is tobe evaluated exclusive of those peaks for the purposes of the presentinvention. Similarly, FIGS. 6 through 10, and FIG. 19 are the infraredspectrums obtained by Fourier Transform Infra Red (FTIR)spectrophotometry of the preceding polymorphs, respectively. It isworthy of note that FTIR is often used to distinguish polymorphs,however these spectra do not exhibit substantial variation forconclusive polymorph diagnosis. Indeed, this phenomenon may have led tothe multitude of polymorphic characteristics of imipramine pamoate beingpreviously unobserved. For additional confirmation of polymorphicidentity and content, thermograms were obtained for each polymorphicform using differential scanning calorimetry (DSC). FIGS. 11 through 15,and FIG. 20 are the thermograms of the identified polymorphic forms,Form I through VI, respectively. FIG. 16 is the HPLC chromatogram of anembodiment of Form II typically employing an aqueous preparationprocess. In contrast, FIG. 17 is the HPLC chromatogram of a purifiedimipramine pamoate prepared by employing a mixed solvent system of waterand an organic solvent. FIG. 21 is the differential scanning calorimetrythermogram of an embodiment of imipramine pamoate subjected to anannealing process.

Beyond the identification of the various polymorphs available toimipramine pamoate, another feature of the invention is the ability toform stable mixtures of at least one polymorph with amorphous imipraminepamoate. It is well known and recognized that amorphous forms of activeingredients have faster dissolution rates than polymorphic forms. Ablended presentation of amorphous and at least one polymorphic form isrepresented in FIGS. 2, 7, and 12, for the PXRD diffractogram, FTIRspectrum and DSC thermogram, respectively.

Yet another important feature of this invention is the ability toproduce stable blends of the polymorphic and amorphous forms.Optionally, the synthetic process can be adjusted to produce polymorphicand/or amorphous mixtures, or a physical blending of individuallyproduced polymorphic forms, said blends optionally containing amorphouscontent, can be prepared. To further elucidate this comparison, Form VIis obtained by a synthetic process which concomitantly producesamorphous material and a single polymorph exhibiting a phase change (byDSC) nominally occurring around 130° C. In contrast, Form V is aphysical admixture of Forms I and III.

Associated with the ability of the synthetic process to produce amixture of amorphous and polymorphic forms is the unusual discovery ofisolating and characterizing meta-stable forms of imipramine pamoatefrom the reaction vessel. More specifically, the selection of thereaction time and/or the reaction temperature provides a mechanism toobtain otherwise elusive polymorphs. It was generally observed thatmeta-stable forms (excluding the amorphous form) were obtained at thelower processing temperatures. However, the fact that stable blends ofamorphous and polymorphic forms were observed across a broad temperaturerange (sufficient for isolation and characterization) indicatesimipramine pamoate exhibits several thermodynamic “wells”. Consequently,the use of the term meta-stable to describe these forms is more relevantto the processing conditions than to their use in practical dosageapplications where the temperature ranges generally do not exceed 50° C.

Yet another feature of the invention is the ability to providesubstantially pure amorphous and/or polymorphic forms of imipraminepamoate. In addition to the preceding purification process and incontrast to traditional recrystallization techniques, an analogous solidstate “recrystallization” technique was achieved by an annealingprocess. It is a feature of the present invention that an imipraminepamoate salt when subjected to an annealing process and optionally inthe absence of solvent induces an enhancement of polymorph purity. Uponheating a mixture of an imipramine pamoate polymorph having amorphouscontent, enrichment of the polymorph was observed. This observationallows for the fine-tuning of polymorph selection in the manufacturingprocess which optionally may include the steps of solvent/anti-solventmethodology for removal of (synthesis) impurities or polymorphenrichment followed by solids isolation and drying under annealingconditions to yield polymorph enrichment. Similarly, polymorphictransitions can be induced in compositions containing substantially onepolymorph by employing an annealing process. For practical application,the annealing step can optionally occur during the manufacturing processwhere 1) the reaction medium of at least one solvent is simultaneouslyremoved during drying and annealing, or 2) applying the annealingprocess to previously isolated and dried material. Often,recrystallization techniques are used to purify pharmaceutically usefulsolids, however, the essentially insoluble nature of imipramine pamoateprevents this approach to purification. Additionally, polymorphintegrity is severely challenged when a given (crude) polymorph isexposed to heat and solvent during a recrystallization process. Duringthe exploration to prepare imipramine pamoate polymorphs, high pressureliquid chromatography (HPLC) was employed to monitor the extent ofpreparative reactions. Similarly, in an attempt to prepare a hydrate,solvate and/or a clathrate form of imipramine pamoate, relatively crudematerial was exposed to a solvent-saturated environment. Bothchromatographic monitoring of reaction conditions and visual analysis ofthe solvent exposures indicated impurities could be removed underspecialized conditions despite the nearly universally insoluble natureof imipramine pamoate in a variety of solvent systems. In an analyticalcomparison of preparative synthetic techniques, the present inventionresulted in achieving essentially pure imipramine pamoate as evidencedby the HPLC chromatograms shown in FIGS. 16 and 17. FIG. 16 reflects theanalysis of the aqueous process typically employed to prepare pamoates.FIG. 17 is indicative of a process employing a mixed solvent system ofwater and an organic solvent. For practical purposes, the organicsolvent was selected from those having miscibility with water (forexample ethanol or ethyl acetate). However, the invention is not limitedor restricted by miscibility of the organic solvent with water and tothe extent purification is accomplished, the organic solvent selectioncan have anti-solvent properties.

In addition to the preceding purification process and in contrast totraditional recrystallization techniques, an analogous solid state“recrystallization” technique was achieved by an annealing process. Itis a feature of the present invention that an imipramine pamoate saltwhen subjected to an annealing process and optionally in the absence ofsolvent induces an enhancement of polymorph purity. Upon heating amixture of an imipramine pamoate polymorph having amorphous content,enrichment of the polymorph was observed. This observation allows forthe fine-tuning of polymorph selection in the manufacturing processwhich optionally may include the steps of solvent/anti-solventmethodology for removal of (synthesis) impurities followed by solidsisolation and drying under annealing conditions to yield polymorphenrichment. Similarly, polymorphic transitions can be induced incompositions containing substantially one polymorph by employing anannealing process. For practical application, the annealing step canoptionally occur during the manufacturing process where 1) the reactionmedium of at least one solvent is simultaneously removed during dryingand annealing, or 2) applying the annealing process to previouslyisolated and dried material.

The discovery of the annealing process provided some insight into themultitude of polymorphs obtained from the different experimentalconditions employed. A trend analysis was performed by comparing eachreaction condition (reagent addition rate, reaction temperature, holdtime, isolation temperature, solvent effect and drying conditions) withthe analytical data characterizing the isolated product. The analysissuggests that increasing the organic solvent content of the reactionmixture leads to a higher phase transition temperature observed in theisolated polymorph when the reaction temperature was elevated. Thereaction hold times and drying conditions do not seem to impact theformation of the polymorphs characterized by a higher temperaturetransition (DSC).

In aqueous systems, the reaction temperature, hold times and dryingconditions are significant factors in determining the polymorphobtained. By way of example, amorphous material is obtained underaqueous conditions with a short hold time. However, as the reaction holdtime is extended, amorphous material is converted to an analyticallyrecognizable polymorph. If the reaction conditions are maintained (withthe exception of lowering the reaction temperature), amorphous materialis generated along with a lower temperature phase transition polymorphthat was originally absent.

The trend observed can be summarized as higher reaction temperaturesyield a higher phase transition polymorph. This observation isconsistent with the previously described annealing process, andindicates a thermodynamic and kinetic momentum leading to a stable, highphase transition temperature polymorph. The situation becomes morecomplex as the solvent polarity of the reaction mixture is altered.However, here too, temperature seems to be the dominating factor suchthat the presence of a non-polar co-solvent employed at lower reactiontemperature provides polymorphs with lower temperature phasetransitions. And, as discussed above, the lower phase transitionpolymorphs (or amorphous material) can be converted to a higher phasetransition temperature polymorph by an annealing process.

Interestingly, tricyclic antidepressants and imipramine in the specific,exhibit therapeutic benefit besides the treatment of depression.Imipramine has been used in the treatment of fibromyalgia, childhoodnocturnal enuresis and other types of urinary incontinence,trichotillomania, post-traumatic stress disorder, panic disorder and toprovide analgesic-like relief for neuropathic pain. Kravitz et al., inthe Journal of Rheumatology, has reported a relationship betweenimipramine binding, serotonin uptake and the link between fibromyalgiaand depression. An overview of the medical treatments for fibromyalgiais well documented on the University of Maryland Medical Center'swebsite, www.umm.edu/patiented/articles.

Jorgensen et al., in clinical Pharmacokinetics, has reported theclinical effects of imipramine treatment of childhood enuresis.Similarly, Lake et al reports in clinical Pharmacology and Therapeuticsthe effects of imipramine in enuretic boys. Imipramine has also beenreported in a review article found in Modern Drug Discovery for thetreatment of urge incontinence particularly in adult females.

A less recognized, or perhaps under-reported condition, is the use ofimipramine in treating trichotillomania (chronic hair pulling). InClinician Review, Whitaker et al. reports the use of tricyclicantidepressants for the treatment of this behavior. Further, Weller etal. reported in the Journal of the American Academy of Child AdolescencePsychiatry the successful treatment of a prepubertal child withimipramine for trichotillomania and a major depressive disorder.

In contrast to trichotillomania, posttraumatic stress disorder (PTSD)has become a common and frequent diagnosis by mental healthprofessionals caring for the victims of hurricanes, terrorist attacksand those people involved in disturbing events occurring in our societyand in the world. Kosten et al. report in the Journal of Nerve andMental Disorders, the use of phenelzine or imipramine in the treatmentof PTSD.

Rynn et al., in the Journal of Clinical Psychopharmacology, report theuse of imipramine and buspirone in patients with panic disorder and whoare discontinuing therapy employing benzodiazepines. Anxiety anddepression symptoms were reduced and facilitated the taper process frombenzodiazepine therapy.

Enggaard et al. report in Pain, the analgesic effect of codeine ascompared to imipramine in different human experimental pain models.Similarly, Rasmussen et al. report in Therapuetic Drug Monitoring thetherapeutic drug monitoring-based imipramine treatment in neuropathicpain.

The preceding therapeutic indications and treatments ascribed toimipramine are applications for the imipramine pamoate polymorphicinventions described herein. The development of imipramine pamoatepharmaceutical compositions are enabled by the novel discovery of theseadditional presentations of imipramine as pamoate polymorphs, amorphousmaterial, and various combinations of the polymorphic forms with andwithout an amorphous component.

The following Experimental descriptions and Examples are illustrative ofhow to practice the invention.

EXPERIMENTAL

Samples were evaluated using a Differential Scanning Calorimeter from TAInstruments (DSC 2010). Prior to analysis of samples, a single-pointcalibration of the TA Instruments DSC 2010 Differential ScanningCalorimeter (DSC 2010) with the element indium as calibration standard(156.6±0.25° C.) was completed.

IR Spectra were obtained in a KBr disc using a Perkin Elmer Spectrum BXFourier Transform Infrared Spectrophotometer. Instrument calibration wasperformed using a NIST traceable polystyrene standard. Spectra wereobtained over the frequency range of 4000 to 600 cm⁻¹ with 32 scans perminute, 4 cm⁻¹ resolution at 2 cm⁻¹ intervals. For the purposes ofdemonstrating the present invention infrared spectra are formed bymixing the sample with potassium bromide. The pamoate (˜8-12 mg/˜8-14%wt/wt) was loaded to dry KBr (˜100-120 mg) then mixed (mortar/pestle). Aportion of this mixture was compressed in a die by employing a minimumamount of pressure to form a thin, and suitably transparent disc. Ablank KBr disc was also prepared and its spectrum subtracted from thatof the sample pamoate.

Powder X-Ray diffraction patterns were acquired on a Scintag XDS2000powder diffractometer using a copper source and a germanium detector.

HPLC analyses were performed on a Waters 1525 Binary HPLC Pumpchromatograph using a Waters 2487 Dual A Absorbance Detector.

Imipramine Pamoate

The pamoate salt of Imipramine can be prepared by treatment ofImipramine with pamoic salt or pamoic acid in a solvent or solvent mix.Imipramine pamoate was prepared by adding a solution of imipramine in anappropriate solvent, e.g. acidic water, to a solution of disodiumpamoate, pamoic acid or other pamoate salt and stirred resulting inprecipitation of the salt.

For the purposes of the present invention the forms of imipraminepamoate will be designated as imipramine pamoate (Form I) throughimipramine pamoate (Form VI) with the forms defined as provided herein.

Imipramine pamoate Form I is defined as having at least onecharacteristic, more preferably at least two characteristics selectedfrom:

a) a phase transition as determined by DSC of 105-113° C. preferablywith a heat of fusion of at least 0.5 Joules per gram and morepreferably 1-2 joules per gram;

b) an x-ray diffraction pattern as of FIG. 1;

c) an infrared spectrum as of FIG. 6,

d) a thermogram as measured by differential scanning calorimetry as ofFIG. 11; and

e) prepared by the process comprising the steps of:

-   -   i) combining the pH adjusted solutions of imipramine        hydrochloride with disodium pamoate,    -   ii) warming the solution to about 53° C. for about 1-2 hours,    -   iii) cooling and precipitating solids from the reaction solution        at a temperature less than 20° C.,    -   iv) collecting the precipitated solids by filtration or        centriguation,    -   v) washing the collected solids, and    -   vi) drying the solids.

In one embodiment the Imipramine pamoate Form I is prepared by the stepsconsisting of:

-   -   i) combining the pH adjusted solutions of imipramine        hydrochloride with disodium pamoate,    -   ii) warming the solution to about 53° C. for about 1-2 hours,    -   iii) cooling and precipitating solids from the reaction solution        at a temperature less than 20° C., and    -   iv) isolating and purifying the sample.

Imipramine pamoate Form II is defined as having at least onecharacteristic, more preferably at least two characteristics selectedfrom:

a) phase transitions as determined by DSC of 108-115° C. and 137-151°C.;

b) an x-ray diffraction pattern as of FIG. 2;

c) an infrared spectrum as of FIG. 7,

d) a thermogram as measured by differential scanning calorimetry as ofFIG. 12 exhibiting phase transitions at about 108-115° C. and at about137-151° C. and having associated heats of fusion of at least 0.5 and 8Joules per gram respectively; and

e) prepared by the process comprising the steps of:

-   -   i) adding the pH adjusted solution of imipramine hydrochloride        in a gradual, metered manner to the pH adjusted solution of        disodium pamoate,    -   ii) warming the reaction solution to about 55° C. until the        polymorphic form appears,    -   iii) cooling and precipitating solids from the reaction mixture        at a temperature less than 25° C.,    -   iv) collecting the precipitated solids by filtration or        centrifugation,    -   v) washing the collected solids, and    -   vi) drying the solids.

In one embodiment the Imipramine pamoate Form II is prepared by theprocess consisting of the steps of:

-   -   i) adding the pH adjusted solution of imipramine hydrochloride        in a gradual, metered manner to the pH adjusted solution of        disodium pamoate,    -   ii) warming the reaction solution to about 55° C. until the        polymorphic form appears,    -   iii) cooling and precipitating solids from the reaction mixture        at a temperature less than 25° C.,    -   iv) isolating and purifying the sample, and    -   v) drying the solids under vacuum at about 88-97° C. for 7-12        hours

Imipramine pamoate Form III is defined as having at least onecharacteristic, more preferably at least two characteristics selectedfrom:

a) a phase transition as determined by DSC of 160-171° C.;

b) an x-ray diffraction pattern as of FIG. 3;

c) an infrared spectrum as of FIG. 8,

d) a thermogram as measured by differential scanning calorimetry as ofFIG. 13 exhibiting a phase transition at about 160-171° C. with a heatof fusion of at least 2 Joules per gram and more preferably 35-55 Joulesper gram; and

e) prepared by the process of:

-   -   i) combining imipramine pamoate Form II with a solvent or        combination of solvents selected from water and short chain        alcohols,    -   ii) warming the mixture to about 76° C. until the polymorphic        form appears iii) cooling and precipitating solids from the        reaction mixture at a temperature less than 25° C.,    -   iv) collecting the precipitated solids by filtration or        centrifugation,    -   v) washing the collected solids with water, and    -   vi) drying the solids under vacuum at about 103° C. for a        sufficient time to provide dry solid.

In one embodiment Imipramine pamoate Form III is prepared by the processconsisting of the steps:

-   -   i) combining imipramine pamoate Form II with a solvent or        combination of solvents selected from water and short chain        alcohols,    -   ii) warming the reaction solution to about 76° C. until the        polymorphic form appears    -   iii) cooling and precipitating solids from the reaction mixture        at a temperature less than 25° C.,    -   iv) isolating and purifying the sample, and    -   v) drying the solids under vacuum at about 99-107° C. for at        least 12 hours.

Imipramine pamoate Form IV is defined as having at least onecharacteristic, more preferably at least two characteristics selectedfrom:

a) a phase transition as determined by DSC of 140-160° C.;

b) an x-ray diffraction pattern as of FIG. 4;

c) an infrared spectrum as of FIG. 9,

d) a thermogram as measured by differential scanning calorimetry as ofFIG. 14 exhibiting phase transition at about 140-160° C. with a heat offusion of at least 18 Joules per gram and more preferably 38-45 Joulesper gram; and

e) prepared by the process of:

-   -   i) combining imipramine pamoate Form III with a solvent or        combination of solvents selected from water and short chain        alcohols,    -   ii) warming the reaction solution to about 70° C. until the        polymorphic form appears    -   iii) cooling and precipitating solids from the reaction mixture        at a temperature less than 25° C.,    -   iv) collecting the precipitated solids by filtration or        centrifugation,    -   v) washing the collected solids, and    -   vi) drying the solids under vacuum at about 103° C. for a        sufficient time to provide dry solids.

In one embodiment the Imipramine pamoate Form IV is prepared by theprocess consisting of:

-   -   i) combining imipramine pamoate Form III with a solvent or        combination of solvents selected from water and short chain        alcohols,    -   ii) warming the reaction solution to about 70° C. until the        polymorphic form appears    -   iii) cooling and precipitating solids from the reaction mixture        at a temperature less than 25° C.,    -   iv) isolating and purifying the sample, and    -   v) drying the solids under vacuum at about 103° C. for at least        19 hours.

Imipramine pamoate Form V is defined as a physical blend of 5-95 wt %Imipramine pamoate Form I and 5-95 wt % Imipramine pamoate Form IIIhaving at least one characteristic, more preferably at least twocharacteristics selected from:

a) an x-ray diffraction pattern as of FIG. 5;

b) an infrared spectrum as of FIG. 10,

c) a thermogram as measured by differential scanning calorimetry as ofFIG. 15 exhibiting phase transitions at about 60-110° C. and 150-170° C.with heats of fusion for each of at least 10 joules per gram and morepreferably 20-28 Joules per gram; and

d) prepared by the process of:

-   -   i) preparing imipramine pamoate Form I and imipramine pamoate        Form    -   ii) combining 5-95 wt % imipramine pamoate Form I and 5-95 wt %        imipramine pamoate Form III,    -   iii) forming a homogenous mixture of the two forms (by mixing,        blending, tumbling, rotating, or by other mechanical action),        and    -   iv) assessing the quality of the polymorphic blend by analytical        methodology selected from differential scanning calorimetry        (DSC), Infrared absorption (IR) and powder x-ray diffraction        (PXRD).

Imipramine pamoate Form V is a blend of Imipramine pamoate Forms I-IVand VI. It is preferred that the blend comprise:

0-100 wt % of imipramine pamoate Form I,

0-100 wt % of imipramine pamoate Form II,

0-100 wt % of imipramine pamoate Form III,

0-100 wt % of imipramine pamoate form IV, and

0-100 wt % of imipramine pamoate form VI.

In one embodiment Form V comprises 20-80 wt % of imipramine pamoate FormI, and in another embodiment Form V comprises 40-60 wt % of imipraminepamoate Form I. In one embodiment Form V comprises 20-80 wt % ofimipramine pamoate Form II, and in another embodiment Form V comprises40-60 wt % of imipramine pamoate Form II. In one embodiment Form Vcomprises 20-80 wt % of imipramine pamoate Form III, and in anotherembodiment Form V comprises 40-60 wt % of imipramine pamoate Form III.In one embodiment Form V comprises 20-80 wt % of imipramine pamoate FormIV, and in another embodiment Form V comprises 40-60 wt % of imipraminepamoate Form IV. In one embodiment Form V comprises 20-80 wt % ofimipramine Form VI, and in another embodiment Form V comprises 40-60 wt% imipramine pamoate Form VI. In a particular embodiment Form Vcomprises 5-95 wt % imipramine pamoate Form I and 5-95 wt % imipraminepamoate Form III.

Imipramine pamoate Form VI is defined as having at least onecharacteristic, more preferably at least two characteristics selectedfrom:

a) phase transitions as determined by DSC of 98-118° C. and 128-145° C.;

b) an X-ray diffraction pattern as of FIG. 18;

c) an infrared spectrum as of FIG. 19;

d) a thermogram as measured by differential scanning calorimetry as ofFIG. 20 exhibiting phase transition at about 98-118° C. and at about128-145° C. and having associated heats of fusion of at least 50 and 8Joules per gram, respectively; and

e) prepared by the process comprising the steps of:

-   -   i) adding the pH adjusted solution of imipramine hydrochloride        in a gradual, metered manner to the pH adjusted solution of        disodium pamoate,    -   ii) warming the solution to about 42° C. until the polymorphic        form appears,    -   iii) cooling and precipitating the solids from the reaction        mixture at a temperature less than about 25° C.,    -   iv) collecting the precipitated solids by filtration or        centrifugation,    -   v) washing the collected solids, and    -   vi) drying the solids.

In one embodiment the imipramine pamoate Form VI is prepared by theprocess consisting of the steps of:

-   -   i) adding the pH adjusted solution of imipramine hydrochloride        in a gradual, metered manner to the pH adjusted solution of        disodium pamoate,    -   ii) warming the reaction solution to about 42° C. until the        polymorphic form appears,    -   iii) cooling and precipitating solids from the reaction mixture        at a temperature less than about 25° C.,    -   iv) collecting the precipitated solids by filtration or        centrifugation,    -   v) washing the collected solids, and    -   vi) drying the solids.

Specifically, each of the following experimental procedures is providedfor Imipramine pamoate, forms I-VI. Detailed experimental procedures forthe polymorph conversion/purification and crystallization processes areprovided as follows:

Example I

Synthesis of Imipramine Pamoate Form I To a solution containing 34.86 gof disodium pamoate in 358.8 g of water was added a dilute NaOH solutionto adjust the solution to about pH 9.4. To a second solution of 51.07 gof Imipramine HCl in 392.0 g of water was added a dilute NaOH solutionto adjust the Imipramine solution to about pH 4.5. The Imipraminesolution was added to the disodium pamoate solution over 3 h. Themixture was stirred and warmed to about 53° C. for 1.5 h. The mixturewas cooled to <20° C. and solids were collected by filtration. The solidcake was washed with water. Relatively dry cake (96.66 g) was sampled.The sample was dried to yield a solid powder characterized by PXRD (FIG.1), IR (FIG. 6) and DSC (FIG. 11). This material was designated as formI according to the following observations: form I (105-113° C.,amorphous); form II (108-115° C. and 137-151° C.); form III (160-171°C.); form IV (140-160° C.), form V (physical blend), and form VI(process mixture).

Example 2

Synthesis of Imipramine Pamoate—(Form II)— To a solution containing38.57 g of disodium pamoate in 424.0 g of water was added a dilute NaOHsolution to adjust the solution to about pH 9.5. The disodium pamoatesolution was adjusted to about pH 9.3 with dilute HCl solution. To asecond vessel containing 56.81 g of imipramine HCl in 405.0 g of waterwas added a dilute NaOH solution to adjust the imipramine solution toabout pH 4.5. The imipramine HCl solution was transferred to a meteredaddition funnel and was added to the disodium pamoate solution overabout 52 min. The reaction mixture was stirred and heated at about 55°C. for approximately 8.75 h then cooled to <25° C. The solids werecollected by filtration and the solid cake was washed with water. Theimipramine pamoate collected was dried at about 93° C. for about 7-12hours (33.22 g) and was characterized by PXRD (FIG. 2), IR (FIG. 7) andDSC (FIG. 12).

Example 3

Synthesis of Imipramine Pamoate—(Form III)—A mixture containing 50.2 gof imipramine pamoate (form II) in 10.0 g of water and 490.0 g ofethanol was stirred and heated to about 76° C. The reaction mixture wasstirred and heated at about 76° C. for 4.25 h then cooled quickly to<25° C. The solids were collected by filtration and the solid cake waswashed with water. Solids were transferred to a drying dish and dried atabout 103° C. under vacuum for >12 h. Imipramine pamoate (47.7 g) wasdried and was characterized by XRD (FIG. 3), IR (FIG. 8) and DSC (FIG.13).

Example 4

Synthesis of Imipramine Pamoate—(Form IV)—A mixture containing 10.04 gof imipramine pamoate (form III) in 98.0 g of water and 2.0 g of ethanolwas stirred and heated to about 70° C. The reaction mixture was stirredand heated at about 70° C. for 24 h then cooled quickly. The solids werecollected by filtration and the solid cake was washed with water. Solidswere transferred to a drying dish and dried at about 103° C. undervacuum for >19 h. imipramine pamoate (8.74 g) was characterized by PXRD(FIG. 4), IR (FIG. 9) and DSC (FIG. 14).

Example 5

Purification of Imipramine Pamoate—To a solution containing 34.92 g ofdisodium pamoate in 369.5 g of USP water was added a dilute solution ofNaOH to adjust to pH 9.4. In another reactor, a dilute solution of NaOHwas added to a solution containing 51.16 g of Imipramine HCl in 398.0 gof USP water to reach about pH 4.5. Imipramine pamoate seed (0.1 g)(form II) was added to the disodium pamoate solution. The Imipramine HClsolution was transferred to the disodium pamoate solution (about 26° C.)over 3.2 h. The mixture was heated from about 26° C. to 53° C. After 16h, 20.0 g of ethyl acetate (EtOAc) was added to the mixture at about 53°C. The reactor was cooled to near 10° C. and stirred for 1.75 h. Thesolids were collected by filtration and washed with water followed bywashing with a EtOAc-water mixture. Solids were dried at about 105° C.HPLC analysis (FIG. 17) indicated a decrease in the observed impuritiescompared with material prepared in the absence of organic solvent (FIG.16).

Example 6

Admixtures of Form 1 and Form III in a multitude of ratios ranging fromabout 5% to 95% were prepared by adding each form in the desired amountto a common vessel and insuring visual homogenization by rotating,tumbling, stirring or agitating the mixing vessel. Aliquots of theblends were analytically characterized. Analyses by PXRD (FIG. 5), IR(FIG. 10) and DSC (FIG. 15) are provided as representativecharacterizations of the admixtures and identified as Form V.Specifically, the analyses reported herein result from testing of ablend comprising an approximately equal ratio of the two forms.

Example 7

Synthesis of Imipramine Pamaote—(Form VI)— A solution of disodiumpamoate (43.88 g) in water (446.0 g) was prepared at a pH of about 9.5.A solution of imipramine HCl (63.38 g) in water (485.0 g) was preparedat a pH of about 4.0. The imipramine HCl solution (552.7 g) was added tothe disodium pamoate solution at a controlled rate over a period ofabout 2.5 hours. After complete addition, the mixture was warmed to near40-42° C. over approximately 4 h. Stirring was continued forapproximately 3 additional hours at near 40-42° C. and then the solidproduct was isolated by filtration and washed with water. Imipraminepamoate (85.22 g) (92.6%) was isolated after drying at (78-80° C.).Throughout the heating process, samples were taken from the mixture andwashed with water then dried. The Imipramine pamoate samples isolated at42° C. (1.25 h) and 42° C. (2.25 h) contained a mixture of amorphousImipramine Pamoate and Form VI. The Imipramine pamoate solid wascharacterized by PXRD (FIG. 18), FTIR (FIG. 19) and DSC (FIG. 20).

Example 8

Imipramine pamoate Form II was dried in a vacuum oven at 110° C. for 60minutes as an annealing process. The material was characterized by DSC(FIG. 21). The thermogram indicated a significant decrease in the amountof amorphous content in Form II and the enhancement of the observedhigher temperature transition.

The present invention has been described with particular reference tothe preferred embodiments without limit thereto. One of skill in the artwould realize additional embodiments, alterations and additions whichare within the metes and bounds of the invention which is morespecifically set forth in the claims appended hereto.

1. An amorphous form of imipramine pamoate characterized by a differential scanning calorimetry (DSC) thermogram exhibiting a phase transition of about 105-113° C. and a heat of fusion of at least 0.5 joules per gram.
 2. The amorphous form of imipramine pamoate of claim 1 wherein said thermogram exhibits a heat of fusion of 1-2 Joules per gram.
 3. A process for preparing the imipramine pamoate of claim 1 comprising the steps of: a) combining the pH adjusted solutions of imipramine hydrochloride with disodium pamoate, b) warming the solution to about 53° C. for about 1-2 hours, c) cooling and precipitating solids from the reaction solution at a temperature less than about 20° C., d) collecting the precipitated solids by filtration or centriguation, e) washing the collected solids, and f) drying the solids.
 4. An amorphous form of imipramine pamoate of claim 1 characterized by an infrared (IR) absorbance spectrum as of FIG.
 6. 5. A process for preparing the imipramine pamoate of claim 4 comprising the steps of: a) combining the pH adjusted solutions of imipramine hydrochloride with disodium pamoate, b) warming the solution to about 53° C. for about 1-2 hours, c) cooling and precipitating solids from the reaction solution at a temperature less than about 20° C., d) collecting the precipitated solids by filtration or centriguation, e) washing the collected solids, and f) drying the solids.
 6. An amorphous form of imipramine pamoate of claim 1 characterized by a powder X-ray diffraction (PXRD) diffraction pattern as of FIG.
 1. 7. A process for preparing the imipramine pamoate of claim 6 comprising the steps of: a) combining the pH adjusted solutions of imipramine hydrochloride with disodium pamoate, b) warming the solution to about 53° C. for about 1-2 hours, c) cooling and precipitating solids from the reaction solution at a temperature less than about 20° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 8. A polymorphic form of imipramine pamoate characterized by a differential scanning calorimetry (DSC) thermogram exhibiting phase transitions at about 108-115° C. and at about 137-151° C. and having associated heats of fusion of at least 0.5 Joules per gram and 8 Joules per gram respectively.
 9. The polymorphic form of imipramine pamoate of claim 8 wherein said associated heats of fusion are 2-4 and 12-15 joules per gram, respectively.
 10. A process for preparing the imipramine pamoate of claim 8 comprising the steps of: a) adding the pH adjusted solution of imipramine hydrochloride in a gradual, metered manner to the pH adjusted solution of disodium pamoate, b) warming the reaction solution to about 55° C. until the polymorphic form appears, c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 11. A polymorphic form of imipramine pamoate of claim 8 characterized by an infrared (IR) absorbance spectrum as of FIG.
 7. 12. A process for preparing the imipramine pamoate of claim 11 comprising the steps of: a) adding the pH adjusted solution of imipramine hydrochloride in a gradual, metered manner to the pH adjusted solution of disodium pamoate, b) warming the reaction solution to about 55° C. until the polymorphic form appears, c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 13. A polymorphic form of imipramine pamoate characterized by a powder X-ray diffraction (PXRD) pattern as of FIG.
 2. 14. A process for preparing the imipramine pamoate of claim 13 comprising the steps of: a) adding the pH adjusted solution of imipramine hydrochloride in a gradual, metered manner to the pH adjusted solution of disodium pamoate, b) warming the reaction solution to about 55° C. until the polymorphic form appears, c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 15. A polymorphic form of imipramine pamoate characterized by a differential scanning calorimetry (DSC) thermogram exhibiting a phase transition of about 160-171° C. and a heat of fusion of at least 2 Joules per gram.
 16. The polymorphic form of imipramine pamoate of claim 15 wherein said heat of fusion is about 35-55 Joules per gram.
 17. A process for preparing imipramine pamoate of claim 15 comprising the steps: a) preparing imipramine pamoate Form II, b) combining imipramine pamoate Form II with a solvent or combination of solvents selected from water and short chain alcohols, c) warming the reaction solution to about 76° C. until the polymorphic form appears, d) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., e) collecting the precipitated solids by filtration or centrifugation, f) washing the collected solids, and g) drying the solids.
 18. A polymorphic form of imipramine pamoate of claim 15 characterized by an infrared (IR) absorbance spectrum as of FIG.
 8. 19. A process for preparing imipramine pamoate of claim 18 comprising the steps: a) preparing imipramine pamoate Form II, b) combining imipramine pamoate Form II with a solvent or combination of solvents selected from water and short chain alcohols, c) warming the reaction solution to about 76° C. until the polymorphic form appears, d) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., e) collecting the precipitated solids by filtration or centrifugation, f) washing the collected solids, and g) drying the solids.
 20. A polymorphic form of imipramine pamoate characterized by a powder X-ray diffraction (PXRD) pattern as of FIG.
 3. 21. A process for preparing imipramine pamoate of claim 20 comprising the steps: a) preparing imipramine pamoate Form II, b) combining imipramine pamoate Form II with a solvent or combination of solvents selected from water and short chain alcohols, c) warming the reaction solution to about 76° C. until the polymorphic form appears d) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., e) collecting the precipitated solids by filtration or centrifugation, f) washing the collected solids, and g) drying the solids.
 22. A polymorphic form of imipramine pamoate characterized by a differential scanning calorimetry (DSC) thermogram exhibiting a phase transition at about 140-160° C. and a heat of fusion of at least 18 Joules per gram.
 23. The polymorphic form of imipramine pamoate of claim 22 wherein said heat of fusion is 38-45 Joules per gram.
 24. A process for preparing imipramine pamoate of claim 22 comprising the steps of: a) combining imipramine pamoate Form III with a solvent or combination of solvents selected from water and short chain alcohols, b) warming the reaction solution to about 70° C. until the polymorphic form appears c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 25. A polymorphic form of imipramine pamoate of claim 22 characterized by an infrared (IR) absorbance spectrum as of FIG.
 9. 26. A process for preparing imipramine pamoate of claim 25 comprising the steps of: a) combining imipramine pamoate Form III with a solvent or combination of solvents selected from water and short chain alcohols, b) warming the reaction solution to about 70° C. until the polymorphic form appears c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 27. A polymorphic form of imipramine pamoate characterized by a powder X-ray diffraction (PXRD) pattern as of FIG.
 4. 28. A process for preparing imipramine pamoate of claim 27 comprising the steps of: a) combining imipramine pamoate Form III with a solvent or combination of solvents selected from water and short chain alcohols, b) warming the reaction solution to about 70° C. until the polymorphic form appears c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 29. A polymorphic blend of imipramine pamoate Form I and imipramine pamoate Form III characterized by a differential scanning calorimetry (DSC) thermogram exhibiting phase transitions of about 60-110° C. and at about 150-170° C. and each possessing a heat of fusion of at least 10 Joules per gram.
 30. The polymorphic form of imipramine pamoate of claim 29 wherein said heats of fusion are 20-28 Joules per gram.
 31. A process for preparing the polymorphic blend of claim 29 comprising the steps of: a) preparing imipramine pamoate Form I and imipramine pamoate Form III, b) combining imipramine pamoate Form I and imipramine pamoate Form III in a desired weight percentage of each component in a common vessel, c) mixing, blending, tumbling, rotating, or by other mechanical action to insure and assure homogenous intermixing of imipramine pamoate Form I and imipramine pamoate Form III to form said polymorphic blend, and d) assessing the quality of the polymorphic blend by analytical methodology selected from differential scanning calorimetry (DSC), Infrared absorption (IR) and powder x-ray diffraction (PXRD).
 32. A polymorphic blend of imipramine pamoate Form I and imipramine pamoate Form III of claim 29 characterized by an infrared (IR) absorbance spectrum as of FIG.
 10. 33. A process for preparing imipramine pamoate of claim 32 comprising the steps of: a) preparing imipramine pamoate Form I and imipramine pamoate Form III, b) combining imipramine pamoate Form I and imipramine pamoate Form III in a desired weight percentage of each component in a common vessel, c) mixing, blending, tumbling, rotating, or by other mechanical action to insure and assure homogenous intermixing of imipramine pamoate Form I and imipramine pamoate Form III to form said polymorphic blend, and d) assessing the quality of the polymorphic blend by analytical methodology selected from differential scanning calorimetry (DSC), Infrared absorption (IR) and powder x-ray diffraction (PXRD).
 34. A polymorphic blend of imipramine pamoate Form I and imipramine pamoate Form III characterized by a powder X-ray diffraction (PXRD) pattern as of FIG.
 5. 35. A process for preparing imipramine pamoate consistent with claim 34 comprising the steps of: a) preparing imipramine pamoate Form I and imipramine pamoate Form III, b) combining imipramine pamoate Form I and imipramine pamoate Form III in a desired weight percentage of each component in a common vessel, c) mixing, blending, tumbling, rotating, or by other mechanical action to insure and assure homogenous intermixing of imipramine pamoate Form I and imipramine pamoate Form III to form said polymorphic blend, and d) assessing the quality of the polymorphic blend by analytical methodology selected from differential scanning calorimetry (DSC), Infrared absorption (IR) and powder x-ray diffraction (PXRD).
 36. A process for preparing purified forms of imipramine pamoate comprising the steps: a) combining the pH adjusted solutions of imipramine hydrochloride and disodium pamoate at a metered or unmetered rate of combination, b) adding an organic solvent to the reaction mixture during the reagent combining step or afterward, c) warming the reaction solution to a temperature less than or equal to the added solvent's azeotropic boiling point, d) cooling and precipitating solids from the reaction mixture, e) collecting the precipitated solids by filtration or centrifugation, f) optionally washing the collected solids with water, solvent or a mixture thereof, g) drying the solids, optionally under vacuum at temperatures sufficient to remove the water and solvent, and h) assessing the quality of the dried solid by chromatographic methods.
 37. A process according to claim 36 whereby said solvent is water immiscible.
 38. A process according to claim 36 whereby said solvent is water miscible.
 39. A process according to claim 36 whereby said solvent is at least one solvent selected from lower carbon chain alkyl and/or aryl alcohols, esters, and ketones.
 40. A blend of at least one imipramine pamoate polymorphic form with another form.
 41. A blend according to claim 40 whereby at least one imipramine pamoate polymorphic form is blended with amorphous imipramine pamoate.
 42. A process for preparing a mixture of polymorphic forms of imipramine pamoate comprising the steps of a) a process temperature change during the reaction between imipramine as its mineral acid salt with a solution of pamoic acid or its salt such that the temperature of reaction providing a lower phase transition form is increased to the temperature range which provides at least one second, higher melting polymorph, and b) the addition of a secondary solvent capable of allowing the reaction temperature to increase to that temperature where at least one additional polymorph is formed, and c) a process temperature change during drying of the isolated solids for the reaction mixture such that the temperature is increased for a time period required to produce at least one additional polymorph.
 43. A process for preparing a mixture of polymorphic forms of imipramine pamoate comprising the steps of: a) preparing the individual forms to be blended selected from the group defined as Form I, Form II, Form III, Form IV, Form V and Form VI, b) combining the desired forms of imipramine pamoate in a pre-determined weight ratio of each component in a common vessel, c) mixing, blending, tumbling, rotating, or by other mechanical action to insure and assure homogenous intermixing of the two forms, and d) assessing the quality of the polymorphic blend by analytical methodology selected from differential scanning calorimetry (DSC), Infrared absorption (IR), powder x-ray diffraction (PXRD) and chromatographic methodology.
 44. A polymorphic form of imipramine pamoate characterized by a differential scanning calorimetry (DSC) thermogram exhibiting phase transitions at about 98-118° C. and at about 128-145° C. and having associated heats of fusion of at least 50 and 8 Joules per gram, respectively.
 45. The polymorphic form of imipramine pamoate of claim 44 wherein said heats of fusion are at least 30 and 5 joules per gram respectively.
 46. The polymorphic form of imipramine pamoate of claim 44 wherein said heats of fusion are 73-82 and 18-27 joules per gram, respectively.
 47. A process for preparing the imipramine pamoate of claim 44 comprising the steps of: a) adding the pH adjusted solution of imipramine hydrochloride in a gradual, metered manner to the pH adjusted solution of disodium pamoate, b) warming the reaction solution to about 42° C. until the polymorphic form appears, c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 48. A polymorphic form of imipramine pamoate of claim 44 characterized by an infrared (IR) absorbance spectrum consistent with and generally comparable to that represented by FIG.
 19. 49. A process for preparing the imipramine pamoate of claim 48 comprising the steps of: a) adding the pH adjusted solution of imipramine hydrochloride in a gradual, metered manner to the pH adjusted solution of disodium pamoate, b) warming the reaction solution to about 42° C. until the polymorphic form appears, c) cooling and precipitating solids from the reaction mixture at temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 50. A polymorphic form of imipramine pamoate characterized by a powder X-ray diffraction (PXRD) pattern consistent with and generally comparable to that represented in FIG.
 18. 51. A process for preparing the imipramine pamoate of claim 50 comprising the steps of: a) adding the pH adjusted solution of imipramine hydrochloride in a gradual, metered manner to the pH adjusted solution of disodium pamoate, b) warming the reaction solution to about 42° C. until the polymorphic form appears, c) cooling and precipitating solids from the reaction mixture at a temperature less than about 25° C., d) collecting the precipitated solids by filtration or centrifugation, e) washing the collected solids, and f) drying the solids.
 52. A synthetic process capable of producing multiple polymorphic forms of imipramine pamoate comprising at least one step selected from: isolating amorphous imipramine pamoate from the reaction vessel; isolating amorphous imipramine pamoate in combination with a selected polymorphic form of imipramine pamoate; isolating a single polymorphic form of imipramine pamoate and isolating a mixture of polymorphic forms of imipramine pamoate.
 53. A synthetic process capable of inter-converting physical forms of imipramine pamoate comprising at least one step selected from subjecting amorphous imipramine pamoate to solvent and temperature conditions sufficient for generating an amount of polymorphic imipramine pamoate from 1-100% of the single polymorph; subjecting an imipramine pamoate polymorph exhibiting a lower phase transition temperature to solvent and temperature conditions sufficient for generating an amount of a second polymorphic form of imipramine pamoate from 1-100% and said second polymorphic form having a higher phase transition temperature and subjecting a mixture of amorphous imipramine pamoate and an imipramine pamoate polymorph exhibiting a lower phase transition temperature to solvent and temperature conditions sufficient for generating an amount of a second polymorphic imipramine pamoate from 1-100%, and said second polymorphic form having a higher phase transition temperature.
 54. A pharmaceutical composition of at least one polymorphic form of imipramine pamoate suitable for use in treating depression, fibromyalgia, childhood nocturnal enuresis and adult urinary incontinence, trichotillomania, post-traumatic stress disorder, panic disorder and to provide analgesic-like relief for neuropathic pain wherein said pharmaceutical composition is a solid.
 55. A pharmaceutical composition comprising a polymorphic form of imipramine pamoate comprising at least one material selected from the group consisting of imipramine pamoate Form I, imipramine pamoate Form II, imipramine pamoate Form III, imipramine pamoate Form IV and imipramine pamoate Form VI, adapted for use in treating depression, fibromyalgia, childhood nocturnal enuresis and adult urinary incontinence, trichotillomania, post-traumatic stress disorder, panic disorder and to provide analgesic-like relief for neuropathic pain wherein said pharmaceutical composition is a solid.
 56. A pharmaceutical composition comprising 1 to 95% amorphous imipramine pamoate and 5-99 wt % of at least one material selected from imipramine pamoate Form II, imipramine pamoate Form III, imipramine pamoate Form IV and imipramine pamoate Form VI wherein said pharmaceutical composition is a solid.
 57. A pharmaceutical composition according to claim 56 exhibiting resistance to ratio changes of the at least one polymorphic form of imipramine pamoate compared to the amorphous imipramine pamoate when subjected to time, temperature and humidity.
 58. A pharmaceutical composition according to claim 56 and presented in a human dosage.
 59. A process capable of inter-converting physical forms of imipramine pamoate at least one step selected from optionally subjecting amorphous imipramine pamoate to temperature conditions sufficient for generating an amount of polymorphic imipramine pamoate from 1-100% of the single polymorph; optionally subjecting an imipramine pamoate polymorph exhibiting a lower phase transition temperature to temperature conditions sufficient for generating an amount of a second polymorphic form of imipramine pamoate from 1-100% and said second polymorphic form having a higher phase transition temperature; optionally subjecting a mixture of amorphous imipramine pamoate and an imipramine pamoate polymorph exhibiting a lower phase transition temperature to temperature conditions sufficient for generating an amount of a second polymorphic imipramine pamoate from 1-100%, and said second polymorphic form having a higher phase transition temperature and optionally subjecting a mixture of amorphous imipramine pamoate and an imipramine pamoate polymorph to temperature conditions sufficient for substantially converting the amorphous imipramine pamoate to the said imipramine pamoate polymorph.
 60. A process according to claim 59 wherein the mixture of amorphous imipramine pamoate and an imipramine pamoate polymorph contains at least one solvent and is dried to yield enhanced concentrations of the said polymorph.
 61. A process according to claim 59 wherein a mixture of imipramine pamoate selected from amorphous, polymorphic and mixtures thereof is subjected to an annealing process to yield a purified polymorphic form.
 62. A pharmaceutical composition comprising: 0-100 wt % of imipramine pamoate with a phase transition of about 105-133° C. and a heat of fusion of at least 0.5 joules per gram; 0-100 wt % of imipramine pamoate with a phase transition of about 108-115° C. with a heat of fusion of at least 0.5 joules per gram and a phase transition of about 137-151° C. with a heat of fusion of at least 8 joules per gram; 0-100 wt % of imipramine pamoate with a phase transition of about 160-171° C. and a heat of fusion of at least 20 joules per gram; 0-100 wt % of imipramine pamoate with a phase transition of about 140-160° C. and a heat of fusion of 18 joules per gram; 0-100 wt % of imipramine pamoate with a phase transition of about 60-110° C. with a heat of fusion of at least 15 joules per gram and a phase transition of about 150-170° C. with a heat of fusion of at least 15 joules per gram; and 0-100 wt % of imipramine pamoate with a phase transition of about 98-118° C. with a heat of fusion of at least 30 joules per gram and a phase transition of about 128-145° C. with a heat of fusion of at least 5 joules per gram wherein said pharmaceutical composition is a solid.
 63. The pharmaceutical composition of claim 62 comprising 20-80 wt % of said imipramine pamoate with a phase transition of about 105-133° C. and a heat of fusion of at least 0.5 joules per gram.
 64. The pharmaceutical composition of claim 62 comprising 40-60 wt % of said imipramine pamoate with a phase transition of about 105-133° C. and a heat of fusion of at least 0.5 joules per gram.
 65. The pharmaceutical composition of claim 62 comprising 20-80 wt % of said imipramine pamoate with a phase transition of about 108-115° C. with a heat of fusion of at least 0.5 joules per gram and a phase transition of about 137-151° C. with a heat of fusion of at least 8 joules per gram.
 66. The pharmaceutical composition of claim 62 comprising 40-60 wt % of said imipramine pamoate with a phase transition of about 108-115° C. with a heat of fusion of at least 0.5 joules per gram and a phase transition of about 137-151° C. with a heat of fusion of at least 8 joules per gram.
 67. The pharmaceutical composition of claim 62 comprising 20-80 wt % of said imipramine pamoate with a phase transition of about 140-160° C. and a heat of fusion of at least 18 joules per gram.
 68. The pharmaceutical composition of claim 62 comprising 40-60 wt % of said imipramine pamoate with a phase transition of about 140-160° C. and a heat of fusion of at least 18 joules per gram.
 69. The pharmaceutical composition of claim 62 comprising 20-80 wt % of said imipramine pamoate with a phase transition of about 160-171° C. and a heat of fusion of at least 20 joules per gram.
 70. The pharmaceutical composition of claim 62 comprising 40-60 wt % of said imipramine pamoate with a phase transition of about 160-171° C. and a heat of fusion of at least 20 joules per gram.
 71. The pharmaceutical composition of claim 62 comprising 20-80 wt % of said imipramine pamoate with a phase transition of about 60-100° C. and a heat of fusion of at least 10 joules per gram and a phase transition of about 150-170° C. and a heat of fusion of at least 10 joules per gram.
 72. The pharmaceutical composition of claim 62 comprising 40-60 wt % of said imipramine pamoate with a phase transition of about 60-100° C. and a heat of fusion of at least 10 joules per gram and a phase transition of about 150-170° C. and a heat of fusion of at least 10 joules per gram.
 73. The pharmaceutical composition of claim 62 comprising 20-80 wt % of said imipramine pamoate with a phase transition of about 98-118° C. and a heat of fusion of at least 30 joules per gram and a phase transition of about 128-145° C. and a heat of fusion of at least 5 joules per gram.
 74. The pharmaceutical composition of claim 62 comprising 40-60 wt % of said imipramine pamoate with a phase transition of about 98-118° C. and a heat of fusion of at least 30 joules per gram and a phase transition of about 128-145° C. and a heat of fusion of at least 5 joules per gram.
 75. The process of claim 53 wherein the said second imipramine pamoate polymorph exhibits a higher polymorphic purity than the material subjected to the process conditions.
 76. The process of claim 53 wherein the said second imipramine pamoate polymorph exhibits a higher chemical purity than the material subjected to the process conditions.
 77. The process of claim 59 wherein an imipramine pamoate polymorph produced exhibits a prominent phase transition occurring at about 137-151° C. and having an associated heat of fusion of at least about 8 joules per gram.
 78. The process of claim 59 wherein an imipramine pamoate polymorph produced exhibits phase transitions at about 100-120° C. and at about 137-151° C. and having associated heats of fusion of at least about 0.5 and 8 joules per gram, respectively.
 79. The process of claim 59 wherein an imipramine pamoate polymorph produced exhibits a higher polymorphic purity than the material subjected to the process conditions. 